KR100627314B1 - Plasma display panel - Google Patents

Abstract

In the PDP of the present invention, a plasma display panel which displays an image by gas discharge using a plurality of discharge cells provided with a sustain electrode and a scan electrode between a first substrate and a second substrate disposed opposite to each other, A partition member extending in an oblique direction to divide, wherein each of the sustain electrodes and the scan electrodes is formed of a combination of a plurality of line portions extending in one direction in a bar shape, and at least one of the line portions It is formed adjacent to the partition member.

Plasma, Electrode, Bus Electrode, Panel, Discharge, Octagon

Description

Plasma Display Panel {PLASMA DISPLAY PANEL}

1 is an exploded perspective view illustrating a part of a plasma display panel according to an exemplary embodiment of the present invention.

FIG. 2 is a cross-sectional view showing a cross section of the incision bonded along the line A-A of FIG.

FIG. 3 is an electrode layout view selectively showing only a partition and a display electrode in FIG. 1.

4 is a diagram illustrating a distribution of light emission luminances of one discharge cell in a plasma display panel.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel, and more particularly, to a plasma display panel in which an electrode structure is improved to improve light emission luminance.

In general, a plasma display panel (PDP) is a display device that realizes an image by using visible light generated by excitation of a phosphor by a vacuum ultraviolet ray (VUV) emitted from a plasma obtained through gas discharge. to be. Such a PDP can realize an ultra-large screen of 60 inches or more within a thickness of only 10 cm, and has a characteristic of excellent color reproducibility and less distortion due to a viewing angle because it is a self-luminous display device such as a CRT. In addition, the manufacturing method is simpler than the liquid crystal display, and thus has advantages in terms of productivity and cost, and thus has been in the spotlight as the next-generation industrial flat panel display and home TV display.

The structure of the PDP has been developed for a long time since the 1970s, and the structure generally known is a three-electrode surface discharge type structure. The three-electrode surface discharge type structure consists of one substrate including a display electrode located on the same surface and another substrate including an address electrode vertically spaced apart from the substrate and having a discharge gas interposed therebetween. to be. In general, the presence or absence of the discharge is determined by the discharge of the address electrode facing the scan electrode independently connected to each line, and the sustain discharge indicating the emission luminance is determined by two electrode groups located on the same plane. Is done.

At this time, in order not to block the light emitted from the PDP, the electrode formed along each discharge cell is formed as a transparent electrode through which light is transmitted. However, since the transparent electrode itself has high resistance, in order to compensate for its conductivity, the metal electrode is combined with the transparent electrode to form the sustain electrode. At this time, since the metal electrode itself does not transmit light, the metal electrode is formed along the widthwise end of the transparent electrode so as not to block the light from the discharge cell.

However, even when the transparent electrode and the metal electrode are acting, since the discharge gap is substantially formed around the discharge gap where the discharge occurs, the starting voltage for the discharge is high. In addition, since the material (e.g., ITO) constituting the transparent electrode is expensive, the production cost of the PDP is increased to reduce the price competitiveness. In addition, since the electrode itself formed in a strip shape on the substrate is composed of a double layer of a transparent electrode and a metal electrode, the work process is complicated, which also increases the production cost.

On the other hand, Figure 4 is a diagram showing the distribution of light emission luminance for one discharge cell in the PDP, it can be seen that there are the following characteristics.

In the drawing, only the sustain electrode 101 and the partition wall 201 are selectively shown, and a graph showing the light emission luminance distribution according to the electrode is shown in the vertical direction based on the drawing by extending the sustain electrode, and the light emission luminance distribution along the partition in the horizontal direction. Is shown. According to this, the closer to the partition wall, the higher the luminance, which is due to the large amount of phosphors coated on the partition wall. have. In addition, the closer the discharge gap W is, the higher the luminescence brightness is, because the intensity of the discharge is the largest in this portion.

The present invention was devised to solve the above problems in view of the above, and to provide a present invention that can stably discharge while improving the aperture ratio of a panel by using a metal electrode.

In order to achieve the above object, the plasma display panel provided by the present invention,

A plasma display panel which displays an image by gas discharge using a plurality of discharge cells provided with a sustain electrode and a scan electrode between a first substrate and a second substrate disposed to face each other, wherein the discharge cells are divided in a diagonal direction. And a partition member that extends, wherein the sustain electrode and the scan electrode are formed by a combination of a plurality of line portions extending in one direction, and one of the plurality of line portions is formed adjacent to the partition member.

In the present invention, the discharge cell is a third partition connecting the ends of the first partition member formed in a direction crossing the scan electrode, the second partition member intersecting the first partition member and the second partition member diagonally. The partition member is partitioned into an octagonal shape.

In this case, at least one of the line portions may be formed inside the discharge cell adjacent to the third partition member.

Each of the sustain electrode and the scan electrode may be spaced apart from the first line part formed over the second partition member and the third partition member in a direction crossing the first partition member, and spaced apart from each other by a predetermined distance toward the inside of the discharge cell. And a third line portion positioned between the first line portion and the second line portion and adjacent to the second partition member and the third partition member.

At this time, it is preferable that the line width of the first line portion is equal to or larger than the line widths of the second and third partition wall members, and larger than the line widths of the second line portion and the third line portion.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

FIG. 1 is a partially exploded perspective view illustrating a plasma display panel according to an embodiment of the present invention, and FIG. 2 is a partially combined cross-sectional view of the A-A line of FIG. 1.

As shown, in the PDP of the present embodiment, the first substrate 10 (hereinafter referred to as 'back substrate') and the second substrate 20 (hereinafter referred to as 'front substrate') are disposed to face each other at predetermined intervals. Color spaced discharge cells 18 formed by the partition wall 16 are provided in the space between the substrates 10 and 20. In the discharge cell 18, a phosphor layer 19, which is excited by ultraviolet rays and emits visible light, is formed along the partition surface 161 and the bottom surface 141, and discharge gas (for example, to generate plasma discharge). Mixed gas containing xenon (Xe), neon (Ne), and the like.

The front substrate 20 is formed of a transparent material such as glass through which visible light can be transmitted so that an image is displayed. In the lower surface 201 of the front substrate 20, display electrodes 25 are formed to correspond to each discharge cell 18 in one direction (the x-axis direction of the drawing). These display electrodes 25 are composed of a scanning electrode 21 and a sustain electrode 23 in their functional operation. The scan electrode 21 selects a discharge cell that is turned on by working with the address electrode 12, and the sustain electrode 23 works with the scan electrode 21 to generate sustain discharge for the selected discharge cell. Formally, the display electrode 25 is formed in a thin bar shape to form an empty space therein. The display electrode 25 will be described in detail later.

The display electrodes 25 are covered by a dielectric layer 28 formed of a dielectric such as PbO, B ₂ O ₃ , SiO _2, and the like, and the dielectric layer 28 is filled with charged particles during discharge. It prevents damage to the display electrodes 25 by directly colliding with and serves to induce charged particles.

The lower surface 281 of the dielectric layer 28 may be covered by a protective film 29 formed of MgO or the like. The protective film 29 may be charged when the charged particles collide directly with the dielectric layer 28 during discharge. ), And when charged particles collide with each other, the secondary electrons may be discharged to increase discharge efficiency.

In addition, the upper surface 101 of the rear substrate 10 facing the front substrate 20 extends in the direction in which the address electrodes 12 intersect the display electrodes 25 (y-axis direction in the drawing), and are spaced apart from each other. In this state, the discharge cells are arranged in a form corresponding to each discharge cell. The address electrodes 12 are covered with a dielectric layer 14 and buried therein, and the partition wall 16 is formed in a predetermined pattern on the dielectric layer 14.

The partition wall 16 includes a first partition member 16a extending in the same direction as the extending direction of the address electrode 12, a second partition member 16b crossing the first partition member 16a, and a first partition wall member 16b intersecting the first partition member 16a. The discharge cell is partitioned by the combination of the 3rd partition member 16c which connects the 1st partition member 16a and the 2nd partition member 16b in diagonal direction. Accordingly, the partition wall 16 according to the present exemplary embodiment has a shape in which the width of each discharge cell 18 positioned along the extension direction of the address electrode 12 becomes narrower as it moves away from the center of the discharge cell 18.

Referring to FIG. 1, the discharge cell 18 is a pair of first partition wall members 16a that protrude in the same direction as the address electrode 12 and a pair of cross cells formed in a direction perpendicular thereto. Up and down by means of the third partition member 16c connecting the second partition member 16b and the ends of the first partition member 16a and the second partition member 16b in an oblique direction to each other. in the y-axis direction).

Here, the first partition member 16a partitions discharge cells of different colors adjacent to each other to prevent cross-talk between the discharge cells, and the second partition member 16b separates the discharge cells into one independent cell. It is partitioned into space. In addition, the third partition member 16c reduces each corner point in the discharge cell 18 to reduce the non-discharge space where no discharge occurs.

In addition, as shown in FIG. 1, the non-discharge area having a substantially rhombus shape is formed at a point where the first partition member 16a and the second partition member 16b intersect, that is, the space surrounded by four neighboring third partition members 16c. 10 may be further formed. The non-discharge region 10 acts to absorb and dissipate heat in the discharge cell, thereby increasing the overall luminous efficiency of the PDP. In addition, the adjacent discharge cells forming one row (y-axis direction in the drawing) are spaced apart by a predetermined distance, and an exhaust passage is formed therebetween, and a joint bar connecting the second partition member 16b to each other ( 161 may be further formed.

In the discharge cells 18, phosphor layers 19 that emit visible light by being excited by ultraviolet rays generated during discharge are formed. This phosphor layer 19 is formed over the wall surface of the partition 16 and the lower surface of the dielectric layer 14 defined by the partition 16 as shown. The phosphor layer 19 may be formed by selecting any one of red, green, and blue phosphors for color expression, and thus divided into red, green, and blue phosphor layers 18R, 18G, and 18B. Can be. As described above, a discharge gas in which neon (Ne), xenon (Xe), and the like are mixed is filled in the discharge cells 18 in which the phosphor layer 19 is disposed.

Hereinafter, the electrode structure according to the present embodiment will be described. The display electrode 25 of the present embodiment is formed of a metal electrode composed of a plurality of line portions without using a transparent electrode. Accordingly, the display electrode is formed to be empty.

3 is a diagram illustrating an electrode structure according to an exemplary embodiment of the present invention. FIG. 3 is an electrode layout view of a partition electrode and a display electrode positioned along the partition wall. Here, the address electrode is not shown.

Referring to FIG. 3, each of the scan electrode 21 and the sustain electrode 23 is formed of a combination of line parts having a bar shape, and has a symmetrical shape. These line portions are elongated in one direction.

The scan electrode 21 or the sustain electrode 23 is composed of at least two line portions spaced apart from each other. Each line portion is elongated in the direction crossing the first partition member 16a (or the direction intersecting with the address electrode), and maintains a constant distance therebetween. Accordingly, the interior of the electrodes 21 and 23 forms an empty space S. Each of the scan electrodes 21 and the sustain electrodes 23 is formed by the combination of the line portions, and the discharge gap G is formed to face each other inside the discharge cell.

In more detail, the display electrode 25 according to the present exemplary embodiment includes a pair of first line portions 211 and 231 facing the discharge cells 18 and positioned in parallel with each other, and between the first line portions 211 and 231. Between the second line portions 212 and 232 and the first line portions 211 and 231 and the second line portions 212 and 232 which are positioned in the discharge cell and face each other inside the discharge cell to form a discharge gap G. It consists of a combination of the third line portions 213 and 233 located at. In this embodiment, since the scan electrode 21 and the sustain electrode 23 are formed in the same shape as each other, the following description will explain the scan electrode 21 and replace the description of the sustain electrode 23.

The first line part 211 is formed in a bar shape of a thin thin plate and is formed to extend in a direction crossing the first partition member 16a. That is, the second partition wall member 18b and the third partition wall member 18c (hereinafter, ' Collectively referred to as a transverse bulkhead.

At this time, the first line portion 211 is formed to be equal to or larger than the line width w1 of the horizontal partition wall. In fact, since the first line portion 211 is formed of a non-transmissive metal electrode, the first line portion 211 absorbs external light and reduces the reflected luminance. Accordingly, the first line portion 211 may cover the horizontal partition wall, thereby improving the clear room contrast of the PDP. In addition, the first line portion 211 is formed to be larger than the line widths d2 and d3 of the second and third line portions 212 and 213 described below.

The second line portion 212 is formed to extend to cross the center of the discharge cell 18 while forming an empty space S therebetween at a predetermined distance from the first line portion 211 (Fig. X-axis direction). Substantially, the first line parts 211 and 231 and the second line parts 212 and 232 are formed to extend in a direction crossing the address electrode 12 (x-axis direction in the drawing) in parallel with each other.

Accordingly, a pair of adjacent second line portions 212 and 232 facing the center of the discharge cell face each other inside the discharge cell 18 to form a discharge gap G, and an electrical signal applied to each electrode. As a result, counter discharge at the initial stage of discharge is formed.

The initial counter discharge started around the discharge gap G is induced between the first line portions 211 and 231 as a surface discharge. At this time, if the distance between the first line portion 211 and 231 and the second line portion 212 and 232 becomes too wide, the discharge is not diffused and thus an appropriate distance should be maintained, which is dependent on various factors involved in plasma discharge. Although it cannot be determined, it is desirable to maintain about 130 (μm) microns within the general driving range.

In addition, the second line portion 212 may further include a recessed portion c having a curved shape having a predetermined curvature. As a result, a long gap G1 is formed with the recess c interposed therebetween, and a short gap G2 is shorter than the long gap G1 between end regions where the recess is not formed.

As the recesses c are formed in the second line part 212, respectively, and the discharge gap G includes the long gap G1 and the short gap G2, the discharge starts at the short gap G2 and the long gap ( In the discharge mechanism that spreads to the entire discharge cell 18 while spreading out to G2), the concave portion c forming the long gap G1 concentrates the discharge in the center so that the discharge can be stably made, and the short gap G2 The end regions other than the recessed portions of FIG. 2 may increase the discharge efficiency by lowering the discharge start voltage.

In addition, the third line part 213 is positioned between the first line part 211 and the second line part 212 so as to have a predetermined distance from the first line part 211 and the second line part 212, respectively. It is formed while extending in one direction while maintaining.

At this time, it is preferable that the third line portion 213 is located inside the discharge cell 18 adjacent to the third partition member 16c. Accordingly, the third line part 213 is formed in a 'V' shape inside the discharge cell.

When the third line part 213 is formed adjacent to the third partition wall member 16c as described above, the phosphor layer 19 formed as the wall surface of the third partition wall member 16c during the discharge process is formed in the third line part ( 213 is excited under the influence of the electric field to emit visible light is emitted. Experimentally, the third line portion 213 is preferably located between 10 and 20 micrometers from the phosphor layer 19. If the distance is smaller than this distance, there is a problem that visible light is blocked due to insufficient space for emitting visible light. If the distance is larger than this distance, the distance between the phosphor layer 19 and the third line part 213 is too far to excite the phosphor. There is a disadvantage that can not be.

On the other hand, the third line portion 213 is preferably formed adjacent to the first line portion 211 rather than the second line portion 212. As described with reference to FIG. 4, since the intensity of discharge is the largest around the discharge gap G, it is possible to prevent the emission luminance from dropping because the third line portion 213 does not cover the emission luminance in the vicinity.

In the present exemplary embodiment, the first to third line portions constituting the scan electrodes 21 and the sustain electrodes 23 may be connected to each other by the connecting portion 214 in the discharge cell.

At this time, the connection part 214 is located along the centerline of the discharge cell 18 so that the distribution of discharge can be made uniformly with respect to the entire discharge cell geometrically, the second line portion (212, 232) The ends thereof are connected to each other and extend to the first line portions 211 and 231 in parallel with the first partition member 16a to be in contact with each other. At this time, the connecting portion 214 is preferably started in the recess (c).

As such, since the first to third line portions spaced apart from each other are connected to each other by the connecting portion 214, the wall charges generated in the discharging process move along the connecting portion 214 to discharge between the second line portions. The opposite discharge formed in the gap G extends to the first line portion and serves to easily form a surface discharge with a long discharge path.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

According to the present invention, since the electrodes are formed in a partially formed empty space, there is an advantage of improving the light emission luminance by improving the aperture ratio of the panel as compared with the prior art. Further, since the discharge gap is formed to face the conductive bus electrodes with the discharge gap therebetween, the discharge start voltage is lowered than before. In addition, since light generated on the wall surface of the partition wall having good light emission brightness is not blocked, light emission brightness higher than before can be exhibited.

In addition, since each line portion is formed in a structure independent from each other, even if a disconnection occurs in any one electrode, the other line portion compensates for the disconnected electrode, thereby causing a defect due to the electrode disconnection of the panel, while the disconnected line portion is different from the other line. By additional compensation, there is an advantage that the luminous efficiency and the luminous brightness can be maintained as it is.

Claims (11)

A plasma display panel which displays an image by gas discharge using a plurality of discharge cells provided with a sustain electrode and a scan electrode between a first substrate and a second substrate disposed to face each other. A partition member extending in a diagonal direction for partitioning the discharge cell; And each of the sustain electrodes and the scan electrodes is formed of a combination of a plurality of line portions extending in length, and one of the plurality of line portions is formed adjacent to the partition member. The method of claim 1, A first partition member formed in a direction in which the discharge cell intersects the scan electrode, a second partition member intersecting the scan cell, and a third partition member connecting the ends of the first partition member and the second partition member diagonally. A plasma display panel partitioned into an octagonal shape. The method of claim 1, One of the line portions is formed inside a discharge cell adjacent to the third partition member. The method of claim 2, Each of the sustain electrode and the scan electrode may be spaced apart from the first line part formed over the second partition member and the third partition member in a direction crossing the first partition member, and spaced apart from each other by a predetermined distance toward the inside of the discharge cell. And a third line portion located between the second line portion and the first line portion and the second line portion, the third line portion being adjacent to the second barrier member and the third barrier member. The method of claim 4, wherein And a line width d1 of the first line portion is equal to or larger than a line width w1 of each of the second partition members. The method of claim 4, wherein And a line width d1 of the first line portion is greater than a line width d2 of the second line portion and a line width d3 of the third line portion. The method of claim 4, wherein A concave portion is formed in the second line portions disposed to correspond to each other in each of the discharge cells to form a long gap G1 and a short gap G2, which are discharge gaps having different sizes. The method of claim 4, wherein And the third line portion is located closer to the first line portion than the second line portion. The method of claim 7, wherein A plasma display panel including a connection part starting from the recess part and connected to the first line part The method according to any one of claims 1 to 8, And the line parts are formed of a metal bus electrode. The method of claim 10, And the line parts are formed to be elongated in parallel to each other so as to extend.

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